Air conditioner and control method of air conditioner

Abstract

An air conditioner including: a converter circuit that is on an electronic substrate and converts an alternating current to a direct current; an inverter circuit that is on the electronic substrate and converts a direct current converted by the converter circuit to an alternating current to operate a motor that drives a compressor; an inverter control circuit that is on the electronic substrate and drives the inverter circuit; and a temperature detector that detects an outside air temperature input to the inverter control circuit, wherein the inverter control circuit includes a locked energization control unit, and the locked energization control unit performs AC locked energization or DC locked energization on the motor in accordance with the outside air temperature detected by the temperature detector.

Claims

1. An air conditioner comprising: a converter circuit that is on an electronic substrate and converts an alternating current to a direct current; an inverter circuit that is on the electronic substrate and converts the direct current converted by the converter circuit to an alternating current to operate a motor that drives a compressor; an inverter control circuit that is on the electronic substrate and drives the inverter circuit; and a temperature detector that detects an outside air temperature input to the inverter control circuit, wherein the inverter control circuit includes a locked energization control unit, and the locked energization control unit configured to selectively perform one of AC locked energization and DC locked energization on the motor in accordance with the outside air temperature detected by the temperature detector, the locked energization control unit is configured to divide the outside air temperature into three temperature ranges by a first set temperature and a second set temperature that is lower than the first set temperature, the locked energization control unit is configured to control heating to both the compressor and the electronic substrate by the DC locked energization in response to the outside air temperature being equal to or lower than the second set temperature, and the locked energization control unit is configured to control heating to the compressor by the AC locked energization in response to the outside air temperature being higher than the second set temperature and is equal to or lower than the first set temperature.

2. The air conditioner according to claim 1, wherein the first set temperture is an upper limit temperature at which refrigerant stagnation occurs.

3. The air conditioner according to claim 1, wherein the second set temperature is a guaranteed minimum temperature of the electronic substrate that ensures operation of the electric substrate.

4. A control method of an air conditioner that includes a converter circuit that is on an electronic substrate and converts an alternating current to a direct current, an inverter circuit that is on the electronic substrate and converts the direct current converted by the converter circuit to an alternating current to operate a motor that drives a compressor, an inverter control circuit that is on the electronic substrate and drives the inverter circuit, and a temperature detector that detects an outside air temperature input to the inverter control circuit, the method being performed by a locked energization control unit included in the inverter control circuit and comprising: determining whether the outside air temperature is equal to or lower than a first set temperature; repeating, when the outside air temperature is higher than the first set temperature, the determining until the outside air temperature becomes equal to or lower than the first set temperature; determining, when the outside air temperature is equal to or lower than the first set temperature, whether the outside air temperature is equal to or lower than a second set temperature; heating, when the outside air temperature is equal to or lower than the first set temperature and is equal to or lower than the second set temperature, both the compressor and the electronic substrate by DC locked energization; and heating, when the outside air temperature is equal to or lower than the first set temperature and is higher than the second set temperature, the compressor by AC locked energization.

5. The control method of an air conditioner according to claim 4, wherein the first set temperature is an upper limit temperature at which refrigerant stagnation occurs.

6. The control method of an air conditioner according to claim 4, wherein the second set temperature is a guaranteed minimum temperature of the electronic substrate that ensures operation of the electric substrate.

7. A control method of an air conditioner that includes a converter circuit that is on an electronic substrate and converts an alternating current to a direct current, an inverter circuit that is on the electronic substrate and converts the direct current converted by the converter circuit to an alternating current to operate a motor that drives a compressor, an inverter control circuit that is on the electronic substrate and drives the inverter circuit, and a temperature detector that detects an outside air temperature input to the inverter control circuit, the method being performed by a locked energization control unit included in the inverter control circuit and comprising: comparing the outside air temperature with a first set temperature and a second set temperature that is lower than the first set temperature; heating, when the outside air temperature is equal to or lower than the second set temperature, both the compressor and the electronic substrate by DC locked energization; and heating, when the outside air temperature is higher than the second set temperature and is equal to or lower than the first set temperature, the compressor by AC locked energization.

8. The control method of an air conditioner according to claim 7, wherein the first set temperature is an upper limit temperature at which refrigerant stagnation occurs.

9. The control method of an air conditioner according to claim 7, wherein the second set temperature is a guaranteed minimum temperature of the electronic substrate that ensures operation of the electric substrate.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a diagram showing the configuration of an outdoor unit of an air conditioner according to an embodiment;

(2) FIG. 2 is a flowchart showing an operation of a locked energization control unit while a compressor in the air conditioner according to the embodiment is stopped; and

(3) FIG. 3 is a flowchart showing an operation of the locked energization control unit while the compressor in the air conditioner according to the embodiment is stopped.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

(4) Exemplary embodiments of an air conditioner according to the present invention will be explained below in detail with reference to the drawings. The present invention is not limited to the embodiments.

(5) Embodiment.

(6) FIG. 1 is a diagram showing the configuration of an outdoor unit of an air conditioner according to an embodiment of the present invention. FIG. 1 shows an outdoor unit 10, which is connected to an AC power supply 1 and includes a motor 4, a compressor 5, an electronic substrate 7, and a temperature detector 8. The outdoor unit 10 and an indoor unit (not shown) are connected to each other by a refrigerant pipe.

(7) As the AC power supply 1, a single-phase AC power supply or three-phase AC power supply may be used. However, a three-phase AC power supply is exemplified here. The motor 4 is a motor that drives the compressor 5. The compressor 5 is a compressor in a refrigeration cycle driven by the motor 4 and transports heat by the refrigerant in the refrigeration cycle. For example, rotary motion of the motor 4 only needs to be converted to reciprocal motion to compress the refrigerant in the compressor 5. The electronic substrate 7 is an electronic substrate that includes a converter circuit 2, an inverter circuit 3, and an inverter control circuit 6. For example, the converter circuit 2 only needs to be constituted by a rectifier circuit formed by connecting diode elements in a bridge configuration, and the converter circuit 2 converts an alternating current from the AC power supply 1 to a direct current. For example, the inverter circuit 3 only needs to be constituted by a plurality of switching elements and diode elements, and the inverter circuit 3 converts a direct current converted by the converter circuit 2 to an alternating current of a predetermined frequency. The frequency of the alternating current is set, for example, to 10 kHz or higher. The inverter control circuit 6 drives the inverter circuit 3. The temperature detector 8 detects an outside air temperature, and the detected outside air temperature is used for drive control of the compressor 5.

(8) The inverter control circuit 6 includes a locked energization control unit 9. The outside air temperature detected by the temperature detector 8 is input to the locked energization control unit 9, and the locked energization control unit 9 executes control of locked energization with respect to the winding of the motor 4. The locked energization is performed without operating the motor 4 and the compressor 5.

(9) FIG. 2 is a flowchart showing an operation of the locked energization control unit 9 while the compressor is stopped. First, the process is started (Step S11), and it is determined whether an outside air temperature T.sub.a is equal to or lower than a first set temperature T.sub.set1 (Step S12). When the outside air temperature T.sub.a is equal to or lower than the first set temperature T.sub.set1 (when YES is determined at Step S12), it is then determined whether the outside air temperature T.sub.a is equal to or lower than a second set temperature T.sub.set2 (Step S13). When the outside air temperature T.sub.a is equal to or lower than the first set temperature T.sub.set1 and is equal to or lower than the second set temperature T.sub.set2 (when YES is determined at Step S12 and Step S13), both the compressor 5 and the electronic substrate 7 are heated by the DC locked energization (Step S14). When the outside air temperature T.sub.a is equal to or lower than the first set temperature T.sub.set1 and is higher than the second set temperature T.sub.set2 (when YES is determined at Step S12 and NO is determined at Step S13), the compressor 5 is heated by the AC locked energization (Step S15). Heating at Steps S14 and S15 only needs to be performed for a predetermined time. It is then determined whether the compressor 5 is stopped after the heating process (Step S16). Even when the outside air temperature T.sub.a is higher than the first set temperature T.sub.set1 (when No is determined at Step S12), it is determined whether the compressor 5 is stopped (Step S16). When the compressor 5 is stopped (when YES is determined at Step S16), the process returns to Step S12 and it is determined whether the outside air temperature T.sub.a is equal to or lower than the first set temperature T.sub.set1. When the compressor 5 is not stopped (when No is determined at Step S16), the process ends (Step S17).

(10) It is assumed that the first set temperature T.sub.set1 is an upper limit temperature at which stagnation of the refrigerant occurs (for example, T.sub.set1=25 C. or higher). If the outside air temperature T.sub.a is equal to or lower than the first set temperature T.sub.set1, stagnation of the refrigerant occurs and the load at the time of startup of the compressor increases, thereby, in some cases, causing problems such as breakage of the compressor, breakage of an electronic component due to increase of the starting current, or failure to start the compressor due to system abnormality. It can be considered to attach a heater to the compressor against these problems. However, the size of the air conditioner increases because of the heater and cost and power consumption increase.

(11) Accordingly, when the outside air temperature T.sub.a is equal to or lower than the first set temperature T.sub.set1, it is only necessary to perform the AC locked energization. The AC locked energization is performed by driving the inverter circuit 3 to apply an AC current of a high frequency to the winding of the motor 4. A refrigerant stagnation phenomenon can be avoided by the AC locked energization.

(12) It is assumed that the second set temperature T.sub.set2 is lower than the first set temperature T.sub.set1 and is a guaranteed minimum temperature of the electronic substrate 7 (for example, T.sub.set2=25 C. or lower). If the outside air temperature T.sub.a is equal to or lower than the second set temperature T.sub.set2, an electronic component on the electronic substrate 7 may malfunction and may be broken. As a measure against this problem, it can be considered to use an electronic component having a low guaranteed minimum temperature. However, if an electronic component having a low guaranteed minimum temperature is used, downsizing may be hindered and cost increases in many cases.

(13) Alternatively, it can be considered to attach a heater to the electronic component. However, in this case, the air conditioner becomes large because of the heater and cost and power consumption increase.

(14) Accordingly, when the outside air temperature T.sub.a is equal to or lower than the second set temperature T.sub.set2, the DC locked energization only needs to be performed. The DC locked energization is performed by driving the inverter circuit 3 to apply a DC current to the winding of the motor 4. By the DC locked energization, it is possible not only to avoid the refrigerant stagnation phenomenon but also to perform preheating of an ambient temperature of the electronic substrate 7 by self-heating of the electronic component on the electronic substrate 7.

(15) In this manner, the operation of the air conditioner can be made appropriate to the outside air temperature by selectively using the AC locked energization and the DC locked energization. That is, while suppressing the power consumption, stagnation of the refrigerant can be suppressed, and the electronic component on the electronic substrate can be prevented from malfunctioning and being broken.

(16) The control method of the air conditioner according to the present invention is not limited to the mode described above. For example, a determination using the outside air temperature T.sub.a, the first set temperature T.sub.set1, and the second set temperature T.sub.set2 may be performed at a time. It is set such that the second set temperature T.sub.set2 is lower than the first set temperature T.sub.set1.

(17) FIG. 3 is a flowchart showing an operation of the locked energization control unit 9 while a compressor is stopped. First, the process is started (Step S21), and the outside air temperature T.sub.a is compared with the first set temperature T.sub.set1 and the second set temperature T.sub.set2 (Step S22). Because the second set temperature T.sub.set2 is lower than the first set temperature T.sub.set1, the temperature range of the outside air temperature T.sub.a is divided into three regions, that is, a case where T.sub.aT.sub.set2 (a case where the outside air temperature T.sub.a is extremely low), a case where T.sub.set2<T.sub.aT.sub.set1 (a case where the outside air temperature T.sub.a is low), and a case where T.sub.set1<T.sub.a (a case where the outside air temperature T.sub.a is not low). In the case where T.sub.aT.sub.set2 (when the outside air temperature T.sub.a is extremely low), both the compressor 5 and the electronic substrate 7 are heated by the DC locked energization as at Step S14 (Step S23). In the case where T.sub.set2<T.sub.aT.sub.set1 (when the outside air temperature T.sub.a is low), the compressor 5 is heated by the AC locked energization as at Step S15 (Step S24). Heating at Steps S23 and S24 only needs to be performed for a predetermined time. After heating or in the case where T.sub.set1<T.sub.a (when the outside air temperature T.sub.a is not low), it is determined whether the compressor 5 is stopped as at Step S16 (Step S25). When the compressor 5 is stopped (when YES is determined at Step S25), the process returns to Step S22 and the outside air temperature T.sub.a is compared with the first set temperature T.sub.set1 and the second set temperature T.sub.set2 (Step S22). When the compressor 5 is not stopped (when NO is determined at Step S25), the process ends (Step S26).

(18) In this manner, a comparison of the outside air temperature T.sub.a with the first set temperature T.sub.set1 and the second set temperature T.sub.set2 may be performed at a time.

(19) As described above, the present invention relates to an air conditioner including: a converter circuit that is on an electronic substrate and converts an alternating current to a direct current; an inverter circuit that is on the electronic substrate and converts a direct current converted by the converter circuit to an alternating current to operate a motor that drives a compressor; an inverter control circuit that is on the electronic substrate and drives the inverter circuit; and a temperature detector that detects an outside air temperature input to the inverter control circuit, wherein the inverter control circuit includes a locked energization control unit, and the locked energization control unit performs AC locked energization or DC locked energization on the motor in accordance with the outside air temperature detected by the temperature detector, thereby performing heating.

(20) According to the air conditioner, specifically, the outside air temperature is divided into three temperature ranges by a first set temperature and a second set temperature that is lower than the first set temperature, and it is only necessary to perform heating by the DC locked energization when the outside air temperature is equal to or lower than the second set temperature and perform heating by the AC locked energization when the outside air temperature is higher than the second set temperature and is equal to or lower than the first set temperature. With such a configuration, the size of the air conditioner does not become large and cost and power consumption are suppressed.

(21) Furthermore, the present invention relates to a control method of an air conditioner that includes a converter circuit that is on an electronic substrate and converts an alternating current to a direct current, an inverter circuit that is on the electronic substrate and converts a direct current converted by the converter circuit to an alternating current to operate a motor that drives a compressor, an inverter control circuit that is on the electronic substrate and drives the inverter circuit, and a temperature detector that detects an outside air temperature input to the inverter control circuit, the method being performed by a locked energization control unit included in the inverter control circuit and including: determining whether the outside air temperature is equal to or lower than a first set temperature; repeating, when the outside air temperature is higher than the first set temperature, the determining until the outside air temperature becomes equal to or lower than the first set temperature; determining, when the outside air temperature is equal to or lower than the first set temperature, whether the outside air temperature is equal to or lower than a second set temperature; heating, when the outside air temperature is equal to or lower than the first set temperature and is equal to or lower than the second set temperature, both the compressor and the electronic substrate by DC locked energization; and heating, when the outside air temperature is equal to or lower than the first set temperature and is higher than the second set temperature, the compressor by AC locked energization.

(22) Furthermore, the present invention relates to a control method of an air conditioner that includes a converter circuit that is on an electronic substrate and converts an alternating current to a direct current, an inverter circuit that is on the electronic substrate and converts a direct current converted by the converter circuit to an alternating current to operate a motor that drives a compressor, an inverter control circuit that is on the electronic substrate and drives the inverter circuit, and a temperature detector that detects an outside air temperature input to the inverter control circuit, the method being performed by a locked energization control unit included in the inverter control circuit and including: comparing the outside air temperature with a first set temperature and a second set temperature that is lower than the first set temperature; heating, when the outside air temperature is equal to or lower than the second set temperature, both the compressor and the electronic substrate by DC locked energization; and heating, when the outside air temperature is higher than the second set temperature and is equal to or lower than the first set temperature, the compressor by AC locked energization. In this manner, a comparison of the outside air temperature with the first set temperature and the second set temperature may be performed at a time.

(23) In the air conditioner and the control method of the air conditioner, it is only necessary to set the first set temperature to an upper limit temperature at which refrigerant stagnation occurs. Accordingly, refrigerant stagnation can be prevented.

(24) In the air conditioner and the control method of the air conditioner, it is only necessary to set the second set temperature to a guaranteed minimum temperature of the electronic substrate. Accordingly, an electronic component on the electronic substrate can be prevented from malfunctioning and being broken.

(25) According to the present invention, an effect is obtained where an air conditioner for which cost and power consumption are suppressed can be obtained without increasing the size of the air conditioner.

(26) Although the invention has been described with respect to specific embodiments for a complete and clear disclosure, the appended claims are not to be thus limited but are to be construed as embodying all modifications and alternative constructions that may occur to one skilled in the art that fairly fall within the basic teaching herein set forth.